Structural element and methods of use thereof

ABSTRACT

A pre-formed structural concrete element for use in the formation of a composite concrete floor of a building or the like, the element comprising: a generally planar base portion having opposing faces; a series of generally parallel spaced apart formations extending from one said faces of the base portion each defining along with an adjacent formation a void space therebetween and wherein the formations terminate in a plateau and have at least a narrow portion and a wide portion between the plateau and the one said faces of the base portion.

BACKGROUND

The present invention relates to structural engineering and more specifically to a structural member capable of use in the construction of structures such as concrete slabs and elements. The invention further relates to methods of use of the structural member including its application in preparatory formwork and as an element in a composite structure including in layered concrete. The invention also relates to structures which employ the structural member. The invention further relates to lightweight structural members used in a variety of concrete structures.

PRIOR ART

Slab beam concrete constructions is widely used in civil and structural engineering. The typical structure will comprise columns of a size dictated by applied such as dead loads and self weight and live loads and of a spacing dictated by loadings and slab spans. Reinforced and pre stressed concrete floors for buildings are generally made in one of two methods. The floors are either cast in situ using supporting temporary formwork, or are formed from pre-cast concrete planks supported on beams or walls which are then typically covered in a relatively thin in situ layer of concrete. Most major construction work of concrete buildings typically relies on the first cast in situ method in which formwork is constructed as a temporary support for structural reinforcing steel over which is poured structural concrete. Cast in situ reinforced concrete floors, require extensive formwork, are relatively time consuming and labour intensive particularly with respect to the assembly and dismantling of formwork and the time required for the in situ concrete to achieve the required strength. Existing construction systems using pre-cast elements have significant cost and other disadvantages including poor underside surface finish, ribbed profiles on the underside necessitating separate ceilings in many applications, difficulty of running services through and lack of flexibility of the type of structures which can be built. These disadvantages render in situ casting construction the preferred method of slab and floor construction.

There are currently three different types of pre-cast floor systems which are in common use in the building industry.

The first system often known as “Hollow Core” relies on the use of extruded, pre-tensioned, concrete generally rectangular planks which include a series of cylindrical holes or voids extending longitudinally along the plank. The planks are laid on the top of beams or walls and concrete is laid in situ over the top of the planks. This construction system can span relatively long distances, but has the disadvantage that it typically has a very poor surface finish on the underside necessitating in many applications a false ceiling or cladding over the concrete finish. The structural planks are typically produced in quite narrow strips requiring many joints and it is difficult to put services through the floor, as it is very difficult to access the voids. Also the planks are relatively thick and the services typically have to be either hung on the underside, also necessitating false ceilings in some applications or the services may be hidden in thick topping concrete.

A second type of system commonly known as “Ultrafloor employs pre-cast ribs in the shape of an inverted T and which are supported on walls or beams, and these ribs support a thin fibre cement panel such as a “Hardie panel” or the like extending between the ribs. A reinforced concrete floor is then laid over the ribs and panel. This floor system produces a ribbed soffit which necessitates the provision of a cover ceiling in most applications, but it does have the advantage that it is relatively easy to run services through, prior to casting the in situ layer. A further disadvantage of Ultrafloor is that it has a limited span both during concrete pouring and as a finished floor. Ultrafloor is limited in the types of floor structure which can be made from the basic panel and from the panel used in conjunction with the shell beam.

Another prior art system of floor construction is known as “Transfloor” in which a relatively thin 50 mm thick plank of concrete includes longitudinally extending steel reinforcing bars in triangular arrangements of groups of three, with one bar forming an ‘apex’ of the triangle spaced above the upper surface of the concrete plank and joined to the other two bars with steel rods. The planks are placed on top of walls or beams and void/void formers are placed on the concrete plank between the reinforcing and a concrete layer floor laid in situ on top of the plank. In the structural engineering industry the term void typically means an absence of concrete rather than an absence of material.

Void formers are most commonly formed by polystyrene blocks although other non cementitious materials such as pipe clay or the like can be used to form voids in concrete members. This system has the disadvantage that it is limited to relatively short spans of about 7 m or so. Also there is a requirement to support the floor with props and bearers at relatively close spacings of between 2 and 4 m while insitu concrete is being poured and is gaining strength. Any discussion of documents, acts, materials, devices, articles or the like which has been included in the present specification is solely for the purpose of providing a context for the present invention. It is not to be taken as an admission that any or all of these matters form part of the prior art base or were common general knowledge in the field relevant to the present invention as it existed before the priority date of each claim of this application.

INVENTION

The present invention seeks to provide an improved plank for use in forming concrete flooring which addresses and at least partially alleviates some of the problems of the prior art assemblies as discussed above.

The present invention provides a structural member capable of use in the construction of structures such as floor assemblies, concrete slabs and structural elements. The invention further provides methods of uses for the structural member including its application in preparatory formwork and as an element in a composite structure including in situ layered concrete. The invention also provides structures which employ lightweight structural concrete members.

In a first aspect of the present invention, there is provided;

a pre-formed structural element for use in forming a concrete floor of a building or the like, the plank comprising: a generally planar base portion; and a series of formations extending from the base portion, defining voids there between and wherein the upper portion of the formation is generally thicker than the lower portion of the formations at the junction with the base.

Preferably the element is manufactured from concrete cast in a mould and the formations are generally parallel spaced apart ribs. The formations have sides which are inclined relative to the planar base.

In its broadest form the present invention comprises:

a generally elongated pre cast structural element for use in the construction of a composite floor and beam slab construction, the structural element comprising;

a base and an upper surface,

at least one formation extending from the upper surface and including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess; the side walls disposed for at least part of their length at an angle other than normal to the to the upper surface.

In another broad form the present invention comprises:

a generally elongated pre cast structural element for use in the construction of a composite floor and beam slab construction, the structural element comprising;

a base and an opposing upper surface,

at least two spaced apart formations extending from the upper surface and including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a tapered recess.

According to a preferred embodiment the tapered recess has a wide portion at the upper surface of the base of the structural element and a narrow portion at or near the plateau of the formations.

Preferably the formations form longitudinal ribs along the length of the element.

Preferably each longitudinal rib is parallel to each other rib with even spacing therebetween. In an alternative embodiment, the element may be tapered along its longitudinal axis such that the ribbed formations converge in the direction of one end and diverge in the direction of an opposite end. This embodiment might be used in a case where the elements are placed in a horizontal curve. Preferably, each rib includes an outward taper such that the plateau of the formation is wider than a junction between the formation and the upper surface of the element. In one embodiment, the taper extends from the plateau of each formation at least part way towards the junction between the formation and the upper surface of the element. In another embodiment, the taper extends the full distance from the plateau to the upper surface of the base of element. In another embodiment the taper is terminated short of the plateau. In a further embodiment there is provided a shoulder associated with the plateau which receives a cover over the recess thereby maintaining a void space in the element.

Preferably each formation has a generally dovetail geometry with a narrow portion at the junction between the upper surface of the element and the formation tapering out to a wide portion at the plateau.

In another broad form the invention comprises: a construction system using a generally elongated pre cast structural element comprising;

a base having a lower underside surface and an opposing upper surface, at least two spaced apart formations extending from the upper surface and including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a tapered recess; wherein the system employs at least one said elements as part of a composite concrete slab, wherein the slab is formed by said at least one element and an overlay layer which abuts said plateau of each said formations.

In another broad form the present invention comprises:

a composite structural floor comprising;

at least one pre cast structural element having

a base having an underside surface and an opposing upper surface,

at least two spaced apart formations extending from the upper surface and each including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess, the side walls disposed at an angle other than normal to the upper surface of the base of the element;

an overlay layer which engages the at least one element via the formations.

In another broad form the present invention comprises:

a composite structural floor comprising;

at least one pre cast structural element having

a base having an underside surface and an opposing upper surface,

at least one spaced apart formation extending from the upper surface and each including a plateau and side walls each defining, a recess, the side walls disposed at an angle other than normal to the upper surface of the base of the element;

an overlay layer which engages the at least one element via the at least one formation.

According to one embodiment when two elements having one formation are abutted the upper surfaces and adjacent walls of each element combine to define a void recess which receives either a void former or overlay concrete.

According to one embodiment, the overlay layer spans between the plateaus of each said formations closing said recess thereby forming voids in said slab. The system is preferably used in the construction of a composite suspended beam and floor slab assembly. The voids improve the structural performance of the element both during construction carrying wet concrete and in the permanent composite structure. They also provide through passages for services. Preferably, the structural elements are formed in a mould which includes a steel base which imparts a smooth high quality surface finish to the element soffit. The voids reduce the weight of the element. The structural geometry of the formations allow more efficient use of concrete in that the so formed composite has a large compression flange at the top of the formations imparting to the composite a high strength to weight ratio for a given span. The elements may therefore be much thinner for a given span than a prior art conventional slab. In one embodiment the side walls of the formations are generally planar and are inclined at an angle less than 90 degrees and around 40° to 70° to the upper surface of the element. The structural element has a versatility allowing the voids to be filled with polystyrene, cement or concrete Alternatively the voids may be retained with empty spaces.

The base portion is preferably reinforced with fabric or steel rods and/or reinforcing fibres and may be pre-stressed respectively by pre tensioning or post-tensioning. Alternatively, the element may be non stressed. In one embodiment the top of the formations receive and support a sheet of material. In use, the building slab elements may be supported on walls or transverse beams arranged to define a floor. Gaps between adjacent like elements are sealed with part of a composite layer. The void spaces in each element are sealed and an in situ layer is poured over the plateaus of each formation.

BRIEF DESCRIPTION OF DRAWINGS

The present invention will now be described according to a preferred but non limiting embodiments and with reference to the accompanying illustrations in which:

FIG. 1 shows an end view of a pre-cast concrete element incorporating an intermediate formation and adjacent voids filled with a polystyrene filler.

FIG. 2 shows an end view of a pre-cast concrete element of FIG. 1 incorporating an intermediate formation and adjacent empty voids typically used as a spine beam.

FIG. 3 shows an isometric view of the spine beam of FIG. 2;

FIG. 4 shows a cross sectional view of a composite beam including the element of FIG. 1 and including an overlay layer.

FIG. 5 shows a cross section of a composite beam comprising an abbreviated element supporting associated elements and an overlay layer disposed over formation plateaus and associated elements.

FIG. 6 shows a perspective view of a banded beam flooring system having two columns with drop panels and two columns without drop panels and including elements arranged for co operation with support columns. An arrangement of temporary propping for this floor system is also shown.

FIG. 7 shows an enlarged abbreviated end view of a portion of a pre-cast concrete element with alternative formation geometry including shoulders.

FIG. 7 a shows an enlarged abbreviated end view of a portion of a pre cast concrete element with alternative formation geometry including radiused walls.

FIG. 8 shows an enlarged cross sectional view of a portion of a pre-cast concrete element with alternative formation geometry including an abbreviated taper.

FIG. 9 shows an enlarged cross sectional view of a portion of a pre-cast concrete element with alternative formation geometry including an abbreviation in the taper near its plateau.

FIG. 10 shows an enlarged cross sectional view of a portion of a pre-cast concrete element with alternative formation geometry including an abbreviation in the taper near its plateau and radiused junction.

FIG. 11 shows an enlarged cross sectional view of a portion of a pre-cast concrete element with alternative formation geometry including a radiused junction.

FIG. 12 shows an enlarged cross sectional view of a portion of a pre-cast concrete element with alternative formation geometry including abutment shoulders and a radiused junction.

FIG. 13 shows a cross sectional elevation of a composite slab including a structural element and a reinforced overlay layer and including an edge profile on a formation which transmits shear to an adjacent member at right angles to it.

FIG. 14 shows a sectional view through the end of the perpendicular member of FIG. 13 showing the method of transmission of shear at an undercut to the ribs of this member.

FIG. 15 shows a perspective view of a flooring assembly which allows production of a flat plate structure or a flat slab with drop panels including an array of structural elements supported by columns according to one embodiment. In this arrangement the soffits of all the precast elements are in the same plane.

FIG. 16 shows a sectional elevation view of a composite slab flooring assembly of the type shown in FIG. 15 including structural elements and composite slab finish regime about support columns.

FIG. 17 shows an enlarged sectional elevation view of the composite slab flooring assembly including structural elements and composite slab finish regime of FIG. 16.

FIG. 18 shows according to an alternative embodiment a perspective view of a composite slab flooring assembly including precast structural elements and composite slab finish regime with cast in situ band beams about support columns.

FIG. 19 shows a sectional elevation view of the composite slab flooring assembly including structural elements and composite slab finish regime of FIG. 18.

FIG. 20 shows an enlarged sectional elevation view of part of the assembly of FIG. 19 including structural elements and composite slab finish regime about a support column.

FIG. 21 shows an enlarged sectional elevation view of the composite slab flooring assembly including structural elements and composite slab finish according to the regime of FIG. 6.

FIG. 22 shows an enlarged view of a part of the assembly of FIG. 21.

FIG. 23 shows a cross sectional view of a shear junction between the side of a composite slab and support column or precast concrete wall.

FIG. 24 shows a sectional view of a shear junction 0 between a composite slab assembly and a support wall/column with alternative orientation of structural element.

DETAILED DESCRIPTION

FIG. 1 shows an end view of a pre-cast concrete element 1 comprising a base 2 having an underside surface 3 and upper surface 4. Element 1 further comprises formations 5, 6 and 7 which define void spaces 8 and 9. Void 8 is defined by upper surface 4 and side walls 10 and 11. Void 9 is defined by upper surface 4 and side walls 12 and 13. In the embodiment of FIG. 1 voids 8 and 9 are filled with polystyrene or similar lightweight material which maintains a lighter weight than an equivalent element with voids filled with concrete or cement. Element 1 typically includes reinforcing (not shown) in base 2, typically reinforced with steel bars or prestressed reinforcement above which two or more polystyrene void formers 14 and 15 preferably in the shape of an isosceles trapezium are located.

Formations 5, 6 and 7 comprise ribs with longitudinal extent and whose width increases as the distance from surface 4 increases so that there is more material at the top of the formations 5, 6 and 7. The embodiment of FIG. 1 shows a symmetrical intermediate formation 6 which is dove tail (or inverted trapezoidal) creating voids which are trapezoidal. Increase in material at the top of the rib plateaus 16, 17 and 18 improves the performance of the element in bending in that it creates a compressive flange of higher capacity and which is more eccentric to the tensile reinforcement. This increase in bending capacity is in comparison to a prior art element having a rectangular formation were employed. Ideally walls 11 and 12 of formation 6 for instance will be disposed at an angle to surface 4 of base 2 of other than 90 degrees. In the example of FIG. 1 the side walls of the ribs extend at an angle of about 50° although the angle could ideally fall within the range of about 45 to 70°.

FIG. 2 shows an end view of the pre-cast concrete element 1 of FIG. 1 with corresponding numbering and incorporating an intermediate formation 6 and adjacent empty voids 8 to 9 with no void formers. The arrangement of FIG. 2 would typically be used as a spine beam. FIG. 3 shows an isometric view of the spine beam of FIG. 2 with corresponding numbering.

FIG. 4 shows a cross sectional view of a composite beam assembly 20 including an element 21 which is similar to element 1 of FIG. 1. Element 21 comprises formations 22, 23, 24 and 25 which define void spaces 26, 27 and 28. Void 26 is defined by upper surface 29 and side walls 30 and 31. Voids 27 and 28 are similarly defined. In the embodiment of FIG. 4 voids 26, 27 and 28 are filled with polystyrene which maintains a lighter weight than an equivalent element with voids filled with concrete or cement. Element 21 includes tensile reinforcing comprising a series of longitudinally extending reinforcing steel rods 32 which may, as required, be pre-tensioned, post-tensioned or unstressed depending on the application and the requirements for element 21. Element 21 includes three polystyrene void formers in respective voids 26, 27 and 28. Formations 22, 23, 24 and 25 comprise ribs of longitudinal extent and whose width increases as the distance from surface 29 to respective plateaus 33, 34, 35 and 36 so there is more material at the top of the formations 22, 23, 24 and 25. The embodiment of FIG. 4 shows symmetrical intermediate formations 23 and 24 which are dove tail (or inverted trapezoidal) creating voids which are trapezoidal. Also in base 37 of element 21 is a sheet of mesh, loose reinforcement or fibre reinforced concrete 39 to provide resilience to handling of the element 21 and help resist cracking and breaking of the element. Typically element 21 would be manufactured in a mould or extruded. Where the element is moulded, it is preferred that a mould having a steel floor is used so that the underside or soffit 40 of base 37 remains smooth. Typically, steel bars 32 will be pre-stressed along with an untensioned fabric 39. An approximately 20 mm to 80 mm layer of concrete is poured into the base of the mould so as to cover the reinforcing steel bars 32. Void formers are then put into position on the top of the base in voids 26, 27 and 28 and the remaining concrete is poured to bring the height of the rib formations ribs up to the top of the void formers. The concrete is then allowed to set before the composite is removed from the mould. Should reinforcement 20 be pre stressed, then it is either pre tensioned before the casting of elements 37 and 22, 23, 24 and 25 or post tensioned after the concrete achieves sufficient strength. Once element 21 is erected in its final position in the structure, a relatively thin overlayer 42 is poured over element 21 evenly supporting the overlayer which adheres to plateaus 33, 34, 35 and 36. As an alternative embodiment overlay layer 42 may be factory cast prior to site installation of the composite.

Alternatively, element 21 may be extruded through a die using a relatively stiff concrete mix. Extrusion is the preferred method where polystyrene void formers are not used, although either method may be used. In use, with reference to FIG. 4, a plurality of concrete elements 21 are placed on top of beams or walls (not shown) and a layer of reinforcement 43 is placed on top of the elements 21 as required. The element 21 is then covered with a relatively thin in situ layer of concrete 42. Because of the design of the elements 21 and in particular, the thickening of the ribs distal from the base 37, element 21 performs well in bending and can be much lighter than other known pre-formed elements. Thus, the system uses less concrete which reduces materials cost. Also, for a building of given height, the building will weigh less and this allows the columns and footings to be less extensive and consequently cheaper. Also as the floors are thinner, the space saved may be equivalent to one or more extra floors in a building.

FIG. 5 shows a cross section of a composite beam assembly 50 including element 51 and an overlay layer 66 disposed over formation plateaus 53, 54 and 55 of formations 56, 57 and 58 which define voids 59 and 60. Located and bearing on plateau 53 is a beam element 63. Located and bearing on plateau 55 is a second element beam 64.

Because the base 49 of the element 51 is relatively thin, it is possible to place reinforcing 67 inside the voids close to the base 49 of the resultant spine beam (element 51) to resist bending of the beam. It is also possible, to place reinforcement 65 at the top of the beam when concrete overlay layer 66 is poured in situ into the spine beam 51 and over adjacent elements 63 and 64.

In a variant of the element cross-section shown in FIGS. 1 to 5, the rib/formation shape of the elements may be varied. Also, the representations shown in FIGS. 1-5 are of indefinite width and it will be appreciated that the elements may include more or less than the numbers of formations/ribs illustrated.

FIG. 6 shows an abbreviated section of a flooring assembly including elements employed as formwork prior to pouring of an overlay layer (not shown) but analogous to overlay layer 66 of FIG. 5. Shown a perspective view of a banded beam flooring system 70 having two columns with drop panels and two columns without drop panels. The system shown includes elements arranged for co operation with support columns. An arrangement of temporary propping 99 for this floor is also shown. Banded beam flooring system 70 includes elements arranged for co operation with support columns 71, 72, 73 and 74. The arrangement of FIG. 6 provides formwork of elements which will provide a base for a composite slab and band beam system similar to the arrangement of FIG. 4 in the slab spanning direction and FIG. 5 in the band spanning direction. System 70 comprises transverse elements 75 of a first span length determined according to structural design requirements. Elements 76 on the outside of columns 71 and 72 and columns 73 and 74 are abbreviated. Transverse elements 75 are supported at their ends on longitudinal spine beam elements 77 and 78. Elements 78 on the outside of columns have been abbreviated for clarity. FIG. 6 shows the assembly of panels prior to the placement of reinforcement along the spine beam elements 77 and 78 and over the entire assembly including elements 75 and 76 and the placement of a concrete layer over the entire assembly. In this arrangement, conventional formwork is used to form the drop panel 79.

It should be noted that Elements 77 and 78 may or may not incorporate void formers. There are two different junctions shown between elements 77 and 78 and the columns 71, 72, 73 and 74. Columns 71 and 72 are either cast with the floor or are precast and are provided with shear keys and the spine beams 77 and 78 abut the columns. In the second form there is a drop panel 79 formed by conventional formwork which connects the spine beams and adjacent slab beams to the column.

The in situ panel 79 produced with conventional formwork may be terminated at the underside plane of the precast panels 77 and 78 or may project below the general floor soffit. Throughout the specification the term soffit will betaken to mean an underside surface of a structural member. Temporary supports 99 may be required as shown to support the whole floor assembly while concrete is being poured and until it acquires sufficient strength.

FIG. 7 shows an enlarged abbreviated end view of a portion of a pre-cast concrete element 80 comprising a base 81 having an underside surface 82 and an upper surface 83. Extending from upper surface 83 are dove tail formations 84 and 85 which define void space 86. Wall 87 of formation 84 terminates at upper plateau 88 in shoulder 89. Likewise wall 90 of formation 85 terminates at upper plateau 91 in shoulder 92. A sheet 93 of fibre cement or the like can be rested on shoulders 89 and 92 spanning void space 86. This obviates the need to include a void former in void space 86. Formations 84 and 85 are generally in the shape of an inverted trapezium.

FIG. 7 a shows an enlarged abbreviated end view of a portion of a pre cast concrete element with alternative formation geometry including radiused walls. In this embodiment, element 94 comprises a base 95 having an underside surface 96 and an upper surface 97. Extending from upper surface 97 is formation 98 including walls 98 a and 98 b which are substantially S shaped each with opposing radii of curvature.

FIG. 8 shows an enlarged abbreviated end view of a portion of a pre-cast concrete element 100 with alternative formation geometry. In this embodiment, element 100 comprises a base 101 having an underside surface 102 and an upper surface 103. Extending from upper surface 103 is formation 104 including walls 105 and 106. Walls 105 and 106 each have a first portion 108 disposed at an angle normal to the plane of surface 103 and a portion 107 at an angle to surface 103 other than normal.

FIG. 9 shows an enlarged abbreviated end view of a portion of a pre-cast concrete element 110 with alternative formation geometry. In this embodiment, element 110 comprises a base 111 having an underside surface 112 and an upper surface 113. Extending from upper surface 113 is formation 114 terminating in plateau 115 and including walls 116 and 117. Walls 116 and 117 are disposed at an angle less than normal to surface 113 and terminate in a perpendicular abbreviation 118.

FIG. 10 shows the embodiment of FIG. 9 with a radiused junction 119 between surface 113 and formation 114.

FIG. 11 shows an enlarged end view of a portion of a pre-cast concrete element 120 with alternative formation 121 geometry including a radiused junction 122 between base 123 and formation 121.

FIG. 12 shows an enlarged end view of a portion of a pre-cast concrete element with alternative formation geometry including abutment shoulders and a radiused junction. Element 130 comprises a base 131 having an underside surface 132 and an upper surface 133. Extending from upper surface 133 are dove tail formations 134 and 135 which define void space 136. Wall 137 of formation 134 terminates at upper plateau 138 in shoulder 139. Likewise wall 140 of formation 135 terminates at upper plateau 141 in shoulder 142. A sheet 143 of fibre cement or the like can be rested on shoulders 139 and 142 spanning void space 136. This obviates the need to include a void former in void space 136. Wall 137 terminates in a radiused portion at the junction of formation 134 and base 131. Likewise wall 140 of formation 135 terminates in a radiused portion 144 at the junction of formation 135 and base 131.

An advantage of the above elements is that where a floor is required to resist bending in a lateral as well as a longitudinal direction, and/or to locally enhance the elements shear capacity, it is possible to remove portions 143 of fibre reinforced cement formwork where present and simply fill the voids with concrete in those areas where such lateral resistance to bending and/or shear capacity, is required. Similarly it is possible, though not as convenient to remove the void formers of FIG. 4 in order to allow the abovementioned local improvements of transverse bending and/or shear capacity to be implemented.

FIG. 13 shows a cross sectional elevation of a composite slab assembly 150 including a structural element 151 and a reinforced overlay layer 152 and including an edge profile 153 on a formation 154 which transmits shear to an adjacent abutment member 155. The arrangement of FIG. 13 is an example of one form of engagement between element 151 and an abutting support. Element 151 includes dovetail formations 156 as described earlier defining voids 157. Edge profile 153 of formation 154 opposes abutment 155 and is arranged to transmit shear forces between element 151 and abutment element 155. Overlay layer 158 is laid over plateaus 159 of formations 154 and is preferably reinforced with a reinforcing steel 160. Element 155 has its void formers terminated a short distance from its end to allow overlay in turn a shear connection with the edge profile 153 of Element 151. In this way a concrete layer 158 to be poured around the dovetail ribs 144 of element 155 and to thus create a shear connection between the overlay concrete 158 and the dovetail ribs 144 and in turn a shear connection is made between elements 155 and 151 as indicated by arrows 161 and 162.

FIG. 14 shows element 155 rotated 90 degrees from its orientation in FIG. 13. Element 155 is incorporated with overlay layer 158 which forms a composite beam structure. Layer 158 co operates with element 155 via dove tail formations 144 which define trapezoidal voids 147. Void 147 includes walls 145 and 146 which receive shear forces transmitted by undercasting via overly layer 158 as shown by arrows 148 and 149. This structural effect is repeated in each void between formations 144.

FIG. 15 shows a perspective view of a flooring assembly including an array of structural elements supported by columns according to one embodiment. Shown is a flooring system 170 including elements arranged for co operation with support columns 171, 172, 173 and 174. The arrangement of FIG. 15 provides a formwork of elements which will provide a base for a composite slab similar to the arrangement of FIGS. 4 and 5. System 170 comprises transverse elements 175 of a first span length determined according to structural design requirements. Elements 176 on the outside of columns 171 and 172 and columns 173 and 174 are abbreviated for clarity. Elements 178 on the outside of columns have been abbreviated for clarity Transverse elements 175 are supported at their ends next to and with their soffits (underside surface) in the same plane as the soffits of the longitudinal spine beam elements 177 and 178. Elements 175 may be temporarily supported independently of the spine elements 177 and 178 or may be supported by temporarily connecting them to spine elements 177 and 178. FIG. 15 shows the assembly of panels prior to the placement of reinforcement along the spine beam elements 177 and 178 and over the entire assembly including elements 175 and 176 and the placement of a concrete layer over the entire assembly. In this arrangement, conventional formwork is used to form the drop panel 179. It should be noted that Elements 177 and 178 may or may not incorporate void formers. The structure produced by this assembly of panels has a flat and planar soffit over the entire underside of the floor. The in situ panel 179 produced with conventional formwork may be terminated at the underside plane of the precast panels 175, 176, 177 and 178 or may project below the general floor soffit.

FIG. 16 shows a sectional elevation view of a column and composite slab flooring assembly of the type shown in perspective view FIG. 15 taken perpendicular to the spine beams 177 and 178. Assembly includes support columns 190 and 191 each supporting respective spine elements 192 and 193. Spanning therebetween are elements 194. On opposite side of column 190 and extending from spine beam element 192 is element 195 abbreviated for clarity. On opposite side of column 191 and extending from spine beam element 193 is element 196 abbreviated for clarity. This arrangement shows the versatility and inter engagement of structural elements which on one hand may be used as a spine beam and on the other hand as transverse span beams. This also demonstrates how the elements can be arranged as formwork in advance of preparation of a composite structural slab. This also demonstrates how all the precast element may be arranged with their soffits co-planar to produce a flat soffit. Elements 195, 192, 194, 193 and 196 are overlaid with overlay layer 197 which completes the slab composite and floor assembly. Reinforcement has been omitted for clarity but it will be appreciated by persons skilled in the art that each representation of floor assembly shown herein would normally include design reinforcement in tensile regions of the composite and to control shrinkage cracking and to enhance the structure's shear capacity.

FIG. 17 shows with corresponding numbering for corresponding parts an enlarged sectional elevation view of the composite slab flooring assembly including structural elements and composite slab finish regime of FIG. 16. This view also shows overlay layer 197. Void formers 187 have been terminated a short distance from the respective ends 185 and 186 of the panels 194 and 195 to allow the overlay concrete to flow around the dovetail ribs 188 and thus form a shear connection with the overlay concrete 197 Spine beam element 192 includes an end formation 198 having an outer profile 199 which co operates with element 194 to establish a shear connection therebetween. Overlay layer 197 locks element 192 to element 194 and assists in transmission of loads. Overlay layer 197 is in one embodiment supported by spine element 192 and covers the void formers or penetrates the voids (not shown) when the void former is absent in elements 194 and 195 thereby completing the layered composite floor structure. Voids 189 of spine element 192 will receive concrete from overlay layer 197 but in a case where void formers are used, overlay layer will sit over (bridge) voids 189.

FIG. 18 shows a perspective view of a flooring assembly 180 including an array of structural elements supported by columns. Flooring assembly 180 includes transverse elements 240 arranged for co operation with support columns 181, 182, 183 and 184. The arrangement of FIG. 18 provides formwork for concrete to be supplied and a base for a composite slab similar to the arrangement of FIG. 15. Assembly 180 comprises transverse elements 240 of a first span length determined according to structural design requirements. Elements 241 on the outside of columns 181 and 183 and elements 242 on the outside of columns 182 and 184 are abbreviated for clarity. Elements 240 are supported at their ends by longitudinal elements 243 and 244 which are cast in situ on conventional formwork. Longitudinal beams 244 and 243 provide an abutment to receive elements 240, 241 and 242.

FIG. 19 shows a sectional elevation view of a composite column slab flooring assembly of the type shown in perspective view FIG. 18. FIG. 19 shows according to an alternative embodiment, a sectional elevation view of a composite slab flooring assembly 200 including structural elements and composite slab finish regime about support columns. Shown are support columns 201 and 202 each supporting respective cast in situ spine beams 203 and 204 which are formed with conventional formwork. Spanning between columns 201 and 202 the supply are elements 205. On opposite side of column 201 and extending from spine beam element 203 is element 206 abbreviated for clarity. On opposite sides of column 202 and extending from spine beam element 204 is element 207 abbreviated for clarity.

FIG. 20 shows with corresponding numbering an enlarged sectional elevation view of the composite slab flooring assembly 200 of FIG. 19 including structural elements 205 206 and 203 and composite slab finish regime of FIG. 19.

FIG. 21 shows a sectional elevation view of a completed composite column slab flooring assembly 210 of the type shown in the perspective view of FIG. 6, when a section is taken through spine beams 77 and 78. Composite slab flooring assembly 210 includes structural elements and composite slab retained about support columns. Banded beam flooring system 210 shows two columns 211 and 212 with drop panels arranged for co operation with the support columns. Flooring system 210 includes transverse elements 215 of a first span length determined according to structural design requirements. Elements 216 on the outside of columns 211 and elements 217 outside column 212 are abbreviated for clarity. Transverse elements 215 are supported at their ends on longitudinal beam elements 213 and 214. Overlay layer 218 is placed over element 215 and beam elements 213 and 214 to complete the floor slab composite.

FIG. 22 shows an enlarged sectional elevation view of the composite slab flooring assembly 210 of FIG. 21 with corresponding numbering.

FIG. 23 shows a cross sectional view of a shear junction 220 between a composite slab assembly 221 and support wall/column 222. Column includes a recess 223 which provides a key in lock for shear transmission at the junction 220. Composite assembly 221 includes structural element 224 having a base 225 and extending therefrom formations 226 defining voids 227. A reinforcing ferrule 235 is embedded in column/wall 222 and engages reinforcing steel 228 which is embedded in overlay layer 229 which lies over plateaus 230. Overlay layer 229 also fills recess 223 and gap 232 between recess 223 and outer profile 233 of formation 234. The co operation between profile 233 and recess 223 when gap 232 is filled in with concrete from overlay layer 229 results in transmission of shear between precast members 224 and column 222 as indicated by arrows 235 and 236.

FIG. 24 shows a sectional view of a shear junction 250 between a composite slab assembly 251 and support wall/column 252. Column includes a recess 253 which provides a key in lock for shear transmission at the junction 250. The void formers of composite assembly 251 are terminated a short distance from the end to facilitate the undercasting of concrete around the ribs 256 of assembly 251 to facilitate the transmission of shear in a manner alike to that demonstrated in FIGS. 13 and 14. Composite assembly 251 includes structural element 254 having a base 255 and extending therefrom formations 256 defining voids 257. A reinforcing ferrule 258 is embedded in column/wall 252 and engages reinforcing steel 259 which is embedded in overlay layer 260 which lies over plateaus 261. Overlay layer 260 also fills recess 253 and gap 262 between recess 253 and the void around the outer profile 254 at the end of element 251 and outer profile of formation 263. The co operation between recess 253 and profile formation 263 when gap 262 is filled in with concrete from overlay layer 260 results in transmission of shear between pre cast members 254 and column 252 as indicated by arrows 264 and 265.

The versatile use of the structural elements described above provides distinct advantages over existing pre-formed concrete elements. The first advantage is that it is relatively easy to put services through the floor in voids between the formations/ribs of the elements. Secondly, the elements can be formed in a mould having a steel base which allows a high quality finish to the soffit of the element.

Thirdly, the provision of the voids reduces the weight of the element and the shape of the formations/ribs provides more concrete at the upper reaches of the composite thereby providing a large compression flange at the top of the ribs where it is required which allows the elements to be much thinner for a given span.

Fourthly, the void formers may be removed to allow overlay concrete to flow around (undercast) the dovetailed formations and engage them for shear connection. This allows these units to be readily joined to adjacent structural elements with in situ concrete producing both neat appearance and a joint which is readily fire rated as opposed to the external steel connections often employed which need to be separately fire protected.

The structural elements which form the composite floor slab have the capacity for long span without intermediate support both during construction when supporting wet concrete and when integral with the completed composite structure. Element dimensions including depth, rib shape, rib spacing, panel width, and the plan shape of the panel may be varied according to design requirements. For instance, wide panels are not restricted by fixed extrusion equipment allowing quick erection of floors with fewer joints.

The elements may be tapered relative to their longitudinal axis, for instance in a case where the elements form a horizontal radiused corner. Reinforcement in both the tensile and compression regions may be varied according to design requirements. No extrusion tools are needed to fabricate panels and the formation/ rib shape and height is largely determined by the void former shape and size which may be readily changed. The elements may be fabricated as plain reinforced, pre tensioned reinforced or post tensioned reinforced members allowing for flexibility of manufacture dictated by design requirements. Since the elements are lightweight pre cast elements, this allows economic transport and efficient lift by crane.

The use of lightweight elements allows for more lightly loaded columns and consequently smaller footings. Shallow structural depth allows more efficient buildings saving on the lengths of services, facades, and allows for more usable building space in areas where there is a height restriction.

Each element has a smooth flat soffit over whole panel width which can be treated as a final finish with no mandatory need for separate suspended ceilings are claddings. The flat soffit combined with shallow structural depth and lack of ceiling space realizes economic operation of air conditioning with no wasted “dead air” between ribs or in ceiling spaces. A further advantage of the element is the access to voids during construction allowing the installation of services in the void areas and through the relatively thin base slab of the composite. The dovetail formations with void blockouts removed provide shear connections to adjacent elements which are both neat, easily made and fire resistant as opposed to the conventional methods of other pre cast systems which either require bulky expensive and unsightly corbels or exposed steelwork which requires fire protection. Very little tooling required for the manufacture of the elements which means a low cost set up, manufacture. Also mobile manufacturing plants are economically feasible. The elements may also be manufactured on the construction site. Finally, irrespective of whether the elements are manufactured with air voids or voids filled with an insulating polystyrene, a floor is created which has optimal sound, heat and fire separation properties.

It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive. 

1-51. (canceled)
 52. A pre cast structural element for use in the construction of a composite floor and beam slab construction, the structural element comprising: a base having an underside surface and an upper surface, at least two spaced apart formations extending from the upper surface at a web junction and each including a plateau and a wall defining, in conjunction with an opposing wall of an adjacent formation, a recess, the walls disposed at an angle other than normal to the upper surface of the base of the structural element; wherein the plateau width dimension of each said formations as viewed in cross section is greater than a width dimension of a corresponding web junction of each said formations.
 53. A structural floor system comprising a composite slab supported by a plurality of support columns; the composite slab comprising; at least one generally elongated pre cast structural element comprising; a base and an upper surface, at least two spaced apart formations extending from the upper surface at a web junction and including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess; wherein the plateau width dimension of each said formations as viewed in cross section is at least seventy percent greater than a width dimension of a corresponding web junction of each said formations; and wherein the composite concrete slab, also comprises an overlay layer which abuts said plateau of each said formations, the composite supported directly or indirectly by said columns.
 54. A suspended composite floor assembly including an array of pre cast structural elements disposed in a first orientation and an array of pre cast structural elements disposed in a second orientation; each structural element comprising: a base having an underside surface and an upper surface, at least two spaced apart formations extending from the upper surface and each including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess, wherein the plateau width dimension as viewed in cross section of each said formations is at least seventy percent greater than a width dimension of a corresponding web junction of each said formations; the side walls disposed at an angle to the opposing upper surface of the base of the element’ the floor assembly further comprising an overlay layer engaging the plateau of the formations.
 55. A generally elongated pre cast structural element for use in the construction of a composite floor and beam slab construction, the structural element comprising; a base and an upper surface, at least one formation extending from the upper surface and including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess; the side walls disposed for at least part of their length at an angle other than normal to the to the upper surface wherein a plateau width dimension as viewed in cross section of each said formations is at least twenty percent greater than a width dimension of a corresponding web junction of each said formations.
 56. A structural element according to claim 52 wherein each recess is defined by a base and walls.
 57. A structural element according to claim 56 wherein each formation is spaced apart from an adjacent formation.
 58. A structural element according to claim 57 wherein the formations form longitudinal ribs along the length of the element.
 59. A structural element according to claim 58 wherein each recess has a wide portion at the upper surface of the base and a narrow portion adjacent the plateau of the formations.
 60. A structural element according to claim 59 wherein each formation has a narrow portion near the upper surface of the base and a wide portion adjacent the plateau of the formation.
 61. A structural element according to claim 60 wherein each formation includes a portion between the plateau and the upper surface of the base having a gradual increase in width as the formation extends away from the base.
 62. A structural element according to claim 61 wherein a tapered region extends at least part way from the plateau of each formation towards the junction between the formation and the upper surface of the base.
 63. A structural element according to claim 62 wherein, the taper extends the full distance from the plateau to the upper surface of the element.
 64. A structural element according to claim 62 wherein the taper is terminated short of the plateau.
 65. A structural element according to claim 62 wherein the formations include a shoulder adjacent the plateau which receives a cover over the recess thereby maintaining a void space in the element between adjacent formations.
 66. A structural element according to claim 63 wherein each formation has a generally dovetail geometry with a narrow portion at the web junction between the upper surface of the element and the formation tapering out to a wide portion at the plateau.
 67. A structural element according to claim 66 wherein walls of the formations are planar but inclined at an angle other than 90 degrees to the upper surface of the element.
 68. A structural element according to claim 67 wherein, the voids are be filled with material selected from polystyrene, cement or concrete.
 69. A structural element according to claim 67 wherein the voids are left empty.
 70. A pre-formed structural concrete element for use in the formation of a composite concrete floor of a building or the like, the element comprising: a generally planar base portion having an upper face and an underside face; a series of generally parallel spaced apart formations extending from the upper face of the base each defining along with an adjacent formation a void space therebetween and wherein the formations terminate in a plateau and have at least a narrow portion and a wide portion between the plateau and the one said faces of the base portion; and wherein the plateau width dimension as viewed in cross section of each said formations is at least twenty percent greater than a width dimension of a corresponding web junction of each said formations.
 71. A pre-formed element according to claim 70 wherein the formations are longitudinal spaced apart ribs extending the length of the element.
 72. A pre-formed element according to claim 71 wherein the ribs include an outward taper from an upper face of the base portion to the plateau
 73. A pre-formed element according to claim 72 wherein the upper portion of the ribs is generally thicker than the lower portion of the ribs.
 74. A pre-formed structural element according to claim 73 wherein longitudinal formations at edges of the element are asymmetrical
 75. A pre-formed structural element according to claim 74 wherein the formations intermediate the edge formations are symmetrical
 76. A pre-formed structural element according to claim 75 wherein an outer edge face of longitudinal formations have a shoulder whose geometry transmits shear forces between abutting elements
 77. A pre-formed structural element according to claim 76 wherein the element is tapered towards one end and relative to a longitudinal axis of the element.
 78. A composite structural floor comprising; at least one pre cast structural element having a base having an underside surface and an opposing upper surface, at least two spaced apart formations extending from the upper surface and each including a plateau and side walls each defining, with an opposing side wall of an adjacent formation, a recess, the side walls disposed at an angle other than normal to the upper surface of the base of the element; wherein the plateau width dimension as viewed in cross section of each said formations is at least twenty percent greater than a width dimension of a corresponding web junction of each said formations; and wherein an overlay layer which engages the at least one element via the formations. 